KR102072689B1 - Nuclear reactor - Google Patents

Abstract

The present invention relates to a safety injection device and a nuclear reactor having the same, the safety injection device accommodates the reactor coolant therein, the safety injection tank disposed higher in the direction than the reactor vessel; One side is connected in communication with the lower portion of the safety injection tank, the other side is connected in communication with the interior of the reactor vessel, safety injection for injecting the reactor coolant contained in the interior of the safety injection tank in the reactor vessel in the event of an accident pipe; And one side is connected in communication with the upper portion of the reactor vessel, the other side comprises a pressure balance pipe connected in communication with the top of the safety injection tank.

Description

Reactor {NUCLEAR REACTOR}

The present invention relates to a passive safety injection device and a nuclear reactor having the same, and more particularly, to a passive safety injection device and a nuclear reactor having the same, a combination of low pressure and high pressure safety injection is more rapid.

Reactor-type reactors (eg, domestic pressurized water reactors, Japanese boiling water reactors) where main equipments (steam generators, pressurizers, reactor coolant pumps, etc.) are installed outside the reactor vessels, and the main equipment It is divided into an integrated reactor (eg SMART reactor) installed inside. In addition, the reactor is divided into a pressurized water reactor that does not allow boiling by pressurizing the inside of the reactor vessel and a boiling water reactor that allows boiling.

In general, a reactor core is located in a reactor vessel of a separate reactor (the National Senate, US AP1000), and a control rod drive is located above the reactor vessel. The reactor vessel and the steam generator are connected by a large pipe, and a reactor coolant pump is installed in the large pipe between the reactor vessel and the steam generator to provide circulating power to the reactor coolant system fluid. In addition, the pressurizer is connected to the large pipe through the surge pipe to control the pressure of the reactor cooling system.

Unlike general industrial power plants, nuclear power plants (nuclear power plants) generate residual heat for a considerable time in the reactor core even after the reactor is stopped, and the amount of residual heat generated decreases rapidly with time. Accordingly, nuclear power plants are equipped with various safety facilities to ensure safety in case of accidents.

Among the safety facilities, the main systems to ensure the soundness of the core are the safety injection system and the residual heat removal system. The safety injection system replenishes the coolant in the reactor when the coolant in the reactor is lost due to pipe breakage connected to the reactor, and the residual heat removal system removes the residual heat generated in the core after the reactor core stops. Play a role.

The conventional safety injection system includes a safety injection tank, and when the pressure inside the reactor drops below the non-condensing gas pressure in the safety injection tank in the event of a low pressure accident such as coolant leakage, the coolant of the low temperature from the safety injection tank is automatically introduced into the reactor. It is configured to be injected into.

However, the conventional safety injection system has a problem that cannot be used in a high pressure accident in which the pressure inside the reactor is higher than the pressure of non-condensed gas in the safety injection tank.

In order to compensate for this, the conventional hybrid safety injection device is connected to the pressure balance pipe to the upper part of the pressurizer or to the low temperature pipe (pipe connected to the inside of the reactor from the steam generator) so that the reactor can be used even in the case of high pressure accident.

At this time, the high temperature pipe is a connection pipe for connecting the steam generator and the reactor to send the high temperature coolant inside the reactor to the steam generator, and the low temperature pipe is connected to the steam generator and the inside of the reactor to connect the low temperature coolant heat exchanged in the steam generator to the reactor. It is a connecting pipe to recover inside.

The pressurizer is connected to the hot pipe through the jungle pipe, so that the pressure balance pipe may be connected to the hot pipe by being connected to the upper portion of the pressurizer.

In the event of high pressure in the reactor, the pressure balance pipe is opened, and the pressure inside the reactor is transferred to the safety injection tank along the pressure balance pipe, so that when the pressure is balanced between the reactor and the safety injection tank, low-temperature coolant is discharged from the safety injection tank. Can be injected into the reactor.

However, the conventional mixed safety injection device has the advantage that it can be used in high pressure and low pressure accidents, but the pressure balance pipe is connected to a low temperature pipe or a high temperature pipe outside the reactor, the high temperature tube or low temperature tube in the high pressure accident of the reactor Since the coolant is injected from the safety injection tank after the pressure balance with the pressure balance, the injection time of the coolant is delayed by the time required for the pressure balance.

In addition, there is a problem that the safety injection performance of the safety injection tank is lowered due to the flow resistance of the high temperature tube and the low temperature tube.

The present invention was created in order to solve the problems in the conventional hybrid safety injection device, by connecting the pressure balance pipe directly to the upper portion of the reactor vessel can be a low-pressure and high-pressure mixed safety injection can be made more quickly, high temperature pipe or low temperature An object of the present invention is to provide a pre-injection blood injection device and a reactor having the same, which can minimize the performance degradation of the safety injection due to the flow path resistance of the pipe.

In order to achieve the above object, the safety injection device according to the present invention, the safety injection tank accommodates the reactor coolant therein, and is disposed higher in the upper direction than the reactor vessel; One side is connected in communication with the lower portion of the safety injection tank, the other side is connected in communication with the interior of the reactor vessel, safety injection for injecting the reactor coolant contained in the interior of the safety injection tank in the reactor vessel in the event of an accident pipe; And one side is connected in communication with the upper portion of the reactor vessel, the other side includes a pressure balance pipe connected in communication with the top of the safety injection tank.

According to an example related to the present invention, a check valve installed in the safety injection pipe; And a pressure balance valve installed on the pressure balance pipe, wherein the pressure balance pipe may be selectively opened and closed according to the operation of the pressure balance valve.

According to an example related to the present invention, a non-condensable gas may be filled in the upper space of the safety injection tank to pressurize the reactor coolant accommodated in the safety injection tank.

According to an example related to the present invention, the pressure balance valve may be opened when the internal pressure of the reactor vessel is higher than the pressure of the non-condensable gas and closed when the pressure is lower than the pressure of the non-condensable gas.

According to an example related to the present invention, the pressure balancing pipe may further include a high pressure safety injection heat exchanger for cooling the reactor coolant discharged from the reactor vessel.

According to an example related to the present invention, the high pressure safety injection heat exchanger may be a water-cooled heat exchanger cooled by cooling water.

According to an example related to the present invention, the high pressure safety injection heat exchanger may be a heat exchanger of one of a fin and tube type, plate type and printed board type heat exchanger.

Reactors of the present invention, the reactor vessel in which the reactor coolant is accommodated; A steam generator disposed outside the reactor vessel and generating steam using heat generated from the reactor coolant; A high temperature tube connected to one side of the reactor vessel and the steam generator, and supplying the reactor coolant from the reactor vessel to the steam generator; A pressurizer connected to the high temperature pipe through a jungle pipe and configured to adjust a pressure of the reactor coolant; A low temperature tube connected to the other side of the steam generator and the reactor vessel and recovering the reactor coolant exchanged from the steam generator to the reactor vessel; And a safety injection device for injecting a reactor coolant into the reactor vessel when the pressure inside the reactor vessel falls below a predetermined pressure, the safety injection apparatus comprising: a safety injection tank disposed higher than the reactor vessel; One side is connected in communication with the lower portion of the safety injection tank, the other side is connected in communication with the interior of the reactor vessel, safety injection for injecting the reactor coolant contained in the interior of the safety injection tank in the reactor vessel in the event of an accident pipe; And one side may be connected in communication with the upper portion of the reactor vessel, the other side may include a pressure balance pipe connected in communication with the upper portion of the safety injection tank.

According to an example related to the reactor of the present invention, the check valve is installed in the safety injection pipe; And a pressure balance valve installed on the pressure balance pipe, wherein the pressure balance pipe may be selectively opened and closed according to the operation of the pressure balance valve.

According to an example related to the reactor of the present invention, the reactor further includes a passive residual heat removal system for removing the residual heat of the core when the core is installed inside the reactor vessel, the passive residual heat removal system, Cooling water storage unit disposed outside; A heat exchanger for removing residual residual heat, which is accommodated in the cooling water inside the cooling water storage unit and condenses the steam generated by the steam generator; And a high pressure safety injection heat exchanger provided in the pressure balance pipe to heat exchange the condensed water provided from the driven residual heat removal heat exchanger and the reactor coolant discharged from the reactor vessel.

According to an example related to the nuclear reactor of the present invention, the passive residual heat removal system, one side is connected to the steam discharge pipe for discharging steam from the steam generator, the other side is connected to the passive residual heat removal heat exchanger, the steam An upper connection pipe for supplying a heat exchanger for removing passive residual heat; And one side connected to the driven residual heat removing heat exchanger, and the other side connected to a water supply pipe for supplying cooling water to the steam generator, and a lower connection pipe for recovering condensate heat exchanged from the steam generator to the steam generator. .

According to an example related to the reactor of the present invention, the passive residual heat removal system, one side is connected to the high pressure safety injection heat exchanger, the other side is connected to the upper connection pipe, the steam of the cooling water passed through the high pressure safety injection heat exchanger An upper circulation pipe for circulating the passive residual heat removal heat exchanger; And one side connected to the lower connection pipe, and the other side connected to the high pressure safety injection heat exchanger, and a lower circulation pipe resupplying the condensed water passing through the passive residual heat removal heat exchanger to the high pressure safety injection heat exchanger. .

According to an example related to the nuclear reactor of the present invention, the passive residual heat removal system, the check valve is installed in the upper circulation pipe, to prevent the flow of steam of the cooling water back; And a circulation valve installed in the lower circulation pipe so as to be opened and closed, and selectively circulating the condensed water to one of the high pressure safety injection heat exchanger and the steam generator.

Referring to the effect of the pre-injection device and the reactor having the same according to the present invention.

First, the pressure balance pipe is connected to the upper end of the reactor vessel and the upper end of the safety injection tank, so that the pressure inside the reactor is transferred directly from the reactor to the upper part of the safety injection tank along the pressure balance pipe, so that the reactor is not only in case of low pressure accident. Even in the event of a high-pressure accident, low-temperature coolant can be injected more quickly from the safety injection tank into the reactor.

Second, since the pressure balance pipe is directly connected to the reactor instead of the hot tube or the cold tube, the time taken for the pressure balance can be shortened by removing the flow path resistance of the hot tube or the cold tube.

Third, the pressure balancing pipe is directly connected to the upper portion of the reactor vessel has the advantage of simplifying the pressure balancing structure.

1 is a conceptual diagram showing a nuclear reactor with a safety injection device according to an embodiment of the present invention.
2 is a conceptual view showing a safety injection device and a nuclear reactor having the same according to another embodiment of the present invention.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings, and the same or similar components will be given the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. The suffixes "module" and "unit" for components used in the following description are given or mixed in consideration of ease of specification, and do not have distinct meanings or roles. In addition, in the following description of the embodiments disclosed herein, when it is determined that the detailed description of the related known technology may obscure the gist of the embodiments disclosed herein, the detailed description thereof will be omitted. In addition, the accompanying drawings are only for easily understanding the embodiments disclosed in the present specification, the technical idea disclosed in the specification by the accompanying drawings are not limited, and all changes included in the spirit and scope of the present invention. It should be understood to include equivalents and substitutes.

Terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

When a component is said to be "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that another component may be present in the middle. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

Singular expressions include plural expressions unless the context clearly indicates otherwise.

In this application, the terms "comprises" or "having" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

1 is a conceptual diagram showing a nuclear reactor with a safety injection device 100 according to an embodiment of the present invention.

The reactor of the present invention may include a reactor vessel 10, a pressurizer 30, a steam generator 20, and a safety injection device 100.

The reactor vessel 10 has an accommodation space to accommodate the coolant therein. The reactor vessel 10 is a vessel that heats a high temperature coolant using heat released from nuclear fuel.

The reactor vessel 10 may be formed in a cylindrical shape. The reactor core 11 may be provided inside the reactor vessel 10.

A nuclear fuel rod is attached to the reactor core 11, and the reactor core 11 is a device that generates heat from the nuclear fuel by nuclear reaction.

The steam generator 20 may be located between the primary system and the secondary system and form and maintain a pressure boundary between the primary system and the secondary system.

In the separate reactor, the steam generator 20 is installed outside the reactor vessel 10.

The steam generator 20 is configured to be supplied with the high temperature coolant of the reactor vessel 10. The high temperature pipe 22 is a connection pipe for supplying a high temperature coolant to the steam generator 20.

One side of the hot tube 22 is communicatively connected to one side of the reactor vessel 10, and the other side of the hot tube 22 is communicatively connected to one side of the steam generator 20. The other side of the hot tube 22 may be connected to the lower side of the steam generator (20).

The steam generator 20 is configured to heat exchange the water with the high temperature coolant received from the reactor vessel 10. The other side of the steam generator 20 is connected to the water supply pipe 1, the water supply pipe 1 is connected to the water supply system 3, can receive a low-temperature cooling water from the water supply system 3 through the water supply pipe (1). have.

Cooling water supplied to the steam generator 20 is a secondary fluid.

The steam generator 20 has a receiving space for accommodating low temperature cooling water. The heat exchanger tube 21 is provided inside the steam generator 20. The heat exchange tube 21 extends to an upper portion of the accommodating space of the steam generator 20 so that the coolant and the high temperature coolant flowing along the heat exchange tube 21 may be heat exchanged.

The low temperature cooling water absorbs heat from the high temperature cooling material, the temperature rises, and steam is generated above the boiling point temperature. The steam discharge tube 4 is connected to the upper end of the steam generator 20, and the steam may be discharged to the outside through the steam discharge tube 4.

The steam discharge pipe 4 is connected to the turbine of the turbine system 6 so that steam can be delivered to the turbine.

The high temperature coolant received from the reactor vessel 10 is cooled along the heat exchanger tube 21 of the steam generator 20 while being deprived of heat by the cooling water and condensed condensed water may be recovered to the reactor vessel 10.

The low temperature tube 24 may be connected between the steam generator 20 and the reactor vessel 10 to recover the condensed water. One side of the cold tube 24 is connected in communication with the lower side of the steam generator 20, the other side of the cold tube 24 is connected in communication with the reactor vessel (10). The cold tube 24 may be disposed lower than the hot tube 22.

The reactor coolant pump 23 may be installed in the low temperature tube 24. The reactor coolant pump 23 is configured to circulate the high temperature coolant inside the reactor. The high temperature coolant may be supplied with power from the reactor coolant pump 23 and supplied to the steam generator 20 along the hot tube 22, and the cooled condensate may be circulated from the steam generator 20 to the reactor vessel 10. .

The steam generator 20 produces steam by transferring the heat of the primary system produced in the reactor core 11 to the secondary system, and the steam produced by the steam generator 20 may be supplied to a turbine and used for power generation. have.

In the separate reactor, the pressurizer 30 is disposed outside the reactor vessel 10.

Pressurizer 30 is a pressure vessel for pressure control of the high temperature coolant of the reactor. Saturated steam is filled in the upper inside of the pressurizer 30. The heater is installed in the pressurizer 30, and when the pressure of the reactor coolant is lower than the preset pressure, the coolant accommodated in the pressurizer 30 may be heated. The water spray nozzle is installed on the inner upper portion of the pressurizer 30, and when the pressure of the reactor coolant is higher than the preset pressure, water may be sprayed on the upper portion of the pressurizer 30 through the spray nozzle to lower the pressure.

The jungle tube 31 may be provided below the pressurizer 30. One side of the jungle tube 31 may be connected in communication with the lower end of the pressurizer 30, and the other side of the jungle tube 31 may be connected to communicate with the high temperature tube 22.

The main reactor such as the steam generator 20 and the pressurizer 30 is separated from the reactor and installed outside, and a large pipe is installed between the main reactors.

When a coolant loss occurs due to pipe breakage in a separate reactor, the reactor level drops rapidly.

Therefore, the present invention provides a safety injection device 100 to more quickly replenish the lost cooling water.

The safety injection device 100 includes a safety injection tank 40, a safety injection pipe 41 and a pressure balance pipe 42.

The safety injection tank 40 is disposed outside the reactor vessel 10.

The safety injection tank 40 has an accommodation space for accommodating low temperature cooling water therein. The non-condensable gas is filled in the upper part of the safety injection tank 40, and the non-condensable gas may pressurize the cooling water contained in the safety injection tank 40.

The safety injection tank 40 is configured to inject low-temperature cooling water when the internal pressure of the reactor drops below a predetermined pressure.

The safety injection tank 40 is disposed higher than the reactor vessel 10. The safety injection tank 40 may inject the coolant at low temperature into the reactor vessel 10 by gravity due to the height difference.

One side of the safety injection pipe 41 is connected in communication with the lower portion of the safety injection tank 40, the other side of the safety injection pipe 41 is connected in communication with the reactor vessel (10). The other side of the safety injection pipe 41 may be connected to the upper side of the reactor vessel (10).

The check valve 43 is installed in the safety injection pipe 41. The check valve 43 is configured to prevent backflow of the cooling water in the safety injection pipe 41. The check valve 43 is opened and closed by the pressure difference between both sides of the safety injection pipe 41, permits the injection of the coolant from the safety injection tank 40 toward the reactor, and vice versa.

In order to use the safety injection system even in a high-pressure accident of the reactor, a pressure balance pipe 42 may be further provided.

One side of the pressure balance pipe 42 is connected in communication with the upper end of the safety injection tank 40, the other side of the pressure balance pipe 42 is connected in communication with the upper end of the reactor vessel (10).

The pressure balance valve 44 may be installed in the pressure balance pipe 42. The pressure balance valve 44 may be adjusted by receiving a control signal from the controller.

For example, the pressure balance valve 44 may be adjusted to be opened in the event of a high pressure accident of the reactor in accordance with a control signal, and closed in the event of a low pressure accident of the reactor.

Therefore, the safety injection action according to the safety injection device 100 of the present invention will be described.

In normal operation, the reactor coolant is heated by the nuclear reaction in the core to a high temperature. The reactor coolant pump 23 circulates the reactor coolant between the steam generator 20 and the reactor vessel 10.

The high temperature coolant moves along the high temperature pipe 22 and is supplied to the steam generator 20, heat exchanged in the steam generator 20, cooled, and condensed.

The coolant condensed in the steam generator 20 moves along the cold tube 24 and is recovered into the reactor vessel 10.

On the other hand, when the low pressure accident of the reactor, such as pipe breakage, if the internal pressure of the reactor falls below a predetermined pressure (pressure of the non-condensable gas charged in the safety injection tank 40), the pressure balance valve 44 is closed The coolant of the safety injection tank 40 may be injected along the safety injection pipe 41 by gravity to be injected into the reactor vessel 10.

The coolant injected through the safety injection pipe 41 descends along the internal structure of the reactor vessel 10 and flows into the core, thereby cooling the core.

In case of high pressure of the reactor, in order to safely inject coolant of the safety injection tank 40 into the reactor vessel 10 even when the internal pressure of the reactor vessel 10 is still higher than the pressure of the safety injection tank 40. The pressure balancing valve 44 may be opened.

When the pressure balance valve 44 is opened, the upper end of the reactor vessel 10 and the upper end of the safety injection tank 40 may be in communication with each other by the pressure balance pipe 42 to achieve a pressure balance. At this time, the internal pressure of the reactor vessel 10 is transmitted to the upper portion of the safety injection tank 40, the upper pressure of the safety injection tank 40 is equal to the reactor vessel 10, the pressure of the non-condensable gas is the reactor vessel ( Safe injection of coolant is possible even if the pressure is lower than 10).

In addition, since the safety injection tank 40 is disposed higher than the reactor vessel 10, the safety injection tank 40 can be safely injected by natural force (driven force) such as gravity, without depending on an active force such as a pump.

2 is a conceptual view illustrating a safety injection apparatus 200 and a nuclear reactor having the same according to another embodiment of the present invention.

In the present embodiment, a heat exchanger for heat-exchanging the low temperature side and the pressure balance pipe 42 of the passive residual heat removal system 50 and the passive residual heat removal system 50 connected to the steam generator 20 is further included. It is different from the embodiment of FIG. 1 described above in that it is provided.

The passive residual heat removal system 50 is a system for removing residual heat generated in the core after the reactor core 11 stops.

The passive residual heat removal system 50 may include a coolant storage unit 51, connection pipes 53 and 54, a high pressure safety injection heat exchanger 60, and a circulation pipe 56 and 55.

The coolant storage unit 51 may be disposed outside the reactor vessel 10 with the steam generator 20 therebetween. The steam generator 20 may be disposed between the coolant storage unit 51 and the reactor vessel 10.

Cooling water storage unit 51 has a receiving space for storing the cooling water therein. The heat exchanger 52 for removing passive residual heat may be accommodated in the coolant storage unit 51. The driven residual heat removing heat exchanger 52 may be installed to be immersed in the cooling water.

The coolant storage unit 51 may be configured to cool the heat exchanger 52 for removing residual residual heat by water cooling.

The passive residual heat removal heat exchanger 52 may be configured to cool the reactor coolant. For example, the passive residual heat removal heat exchanger 52 may be connected to the steam generator 20 to remove residual heat of the reactor coolant through the steam generator 20.

The residual heat exchanger for driven residual heat 52 may be a heat exchanger of one of a fin and tube type, a plate type, and a printed board type heat exchanger.

An upper connection pipe 53 may be installed at the upper portion of the cold storage part.

One side of the upper connection pipe 53 is connected in communication with the steam discharge pipe 4, the other side of the upper connection pipe 53 may be connected in communication with the upper portion of the heat exchanger 52 for removing residual residual heat.

Heat exchanger 52 for driven residual heat removal is connected to the upper portion of the steam generator 20 through the upper connection pipe 53 and the steam discharge pipe (4), the steam generated in the steam generator 20 for the removal of passive residual heat May be supplied to the heat exchanger 52.

The other side of the upper connection pipe 53 may be connected to the turbine. As a result, steam generated by the steam generator 20 may be supplied to the turbine from the upper connection pipe 53.

Opening and closing valve is installed in the connecting pipe connecting the upper connecting pipe 53 and the turbine system 6, the steam generated in the steam generator 20 in accordance with the opening and closing operation of the opening and closing valve heat exchanger 52 for removal of residual residual heat May be supplied to the turbine or to the turbine.

The coolant storage unit 51 may be disposed higher than the steam generator 20.

The lower connection pipe 54 may be installed at the lower portion of the coolant storage unit 51. One side of the lower connection pipe 54 is connected in communication with the lower portion of the passive residual heat removal heat exchanger 52, the other side of the lower connection pipe 54 is connected to the water supply pipe 1, the heat exchanger for passive residual heat removal ( Condensed water cooled in 52 may be recovered to the steam generator (20).

The pressure balance pipe 42 may be further provided with a high pressure safety injection heat exchanger (60). The high pressure safety injection heat exchanger 60 installed in the pressure balance pipe 42 may be configured to cool the reactor coolant flowing along the pressure balance pipe 42.

The high pressure safety injection heat exchanger 60 may be one of a fin and tube type, plate type and printed board type heat exchanger.

The high pressure safety injection heat exchanger 60 may include a first heat exchange tube 61 through which a reactor coolant flows and a second heat exchange tube 62 through which coolant flows. The first heat exchange tube 61 and the second heat exchange tube 62 may be configured to exchange heat with each other. As a result, the reactor coolant flowing along the first heat exchange tube 61 may be cooled by the cooling water flowing along the second heat exchange tube 62.

The pressure balance pipe 42 is secured at the upper end of the first pressure balance pipe 42 extending from the upper portion of the reactor vessel 10 to the lower end of the high pressure safety injection heat exchanger 60, and the high pressure safety injection heat exchanger 60. It may be composed of a second pressure balance pipe (42) extending to the upper end of the injection tank (40).

One side of the first pressure balance pipe 42 is connected in communication with the reactor vessel 10, and the other side of the first pressure balance pipe 42 is connected in communication with the lower inlet of the first heat exchange pipe 61. The reactor coolant may be transferred from the reactor vessel 10 to the first heat exchange tube 61.

One side of the second pressure balance pipe 42 is connected in communication with the upper outlet of the first heat exchange tube 61, and the other side of the second pressure balance pipe 42 is connected in communication with the upper end of the safety injection tank 40. As a result, the reactor coolant (steam) passing through the first heat exchange tube 61 may be delivered to the safety injection tank 40.

A circulation pipe may be installed between the passive residual heat removal heat exchanger 52 and the high pressure safety injection heat exchanger 60.

The circulation pipe may include an upper circulation pipe 56 through which the coolant passed through the high pressure safety injection heat exchanger 60 and a lower circulation pipe 55 through which the coolant passed through the heat exchanger 52 for removing passive residual heat flows. .

One side of the upper circulation pipe 56 is connected in communication with the upper outlet of the second heat exchange pipe 62, the other side of the upper circulation pipe 56 is connected to one side of the upper connection pipe 53 or the upper connection pipe 53 Bypass) may be connected to the upper inlet of the heat exchanger 52 for driven residual heat removal. In this embodiment, one side of the upper circulation pipe 56 is shown to be connected to the upper connection pipe (53). According to this, the pipe connection structure through which the coolant flowing through the high pressure safety injection heat exchanger 60 can be simplified.

One side of the lower circulation pipe 55 is connected in communication with the lower outlet of the driven residual heat removal heat exchanger 52, the other side of the lower circulation pipe 55 is the second heat exchange pipe of the high pressure safety injection heat exchanger (60) 62).

The lower circulation pipe 55 may be connected to the lower connection pipe 54 or bypass the lower connection pipe 54 to be connected to the heat exchanger 52 for removing the residual residual heat. In this embodiment, one side of the lower circulation pipe 55 is shown connected to the lower connection pipe (54). According to this, the pipe connection structure through which the coolant flowing through the heat exchanger 52 for removing passive residual heat flows can be simplified.

The check valve 58 is installed in the upper circulation pipe 56, and the circulation direction of the cooling water may be restricted in one direction. For example, the check valve 58 may allow the cooling water to move from the high pressure safety injection heat exchanger 60 to the driven residual heat removal heat exchanger 52 and vice versa.

The circulation valve 57 is installed in the lower circulation pipe 55, and the moving direction of the condensed water discharged from the heat exchanger 52 for removing residual residual heat may be determined according to the opening and closing operation of the circulation valve 57.

For example, when the circulation valve 57 of the lower circulation pipe 55 is closed, condensed water is recovered from the driven residual heat removing heat exchanger 52 to the steam generator 20, and when the circulation valve 57 is opened, the condensed water is circulated downward. It may be circulated to the high pressure safety injection heat exchanger 60 along the pipe 55.

At this time, the circulation valve 57 and the water supply valve 2 may be operated in the opposite direction. When the circulation valve 57 is opened, the water supply valve 2 may be closed. On the contrary, when the circulation valve 57 is closed, the water supply valve 2 may be opened.

Referring to the operation of the passive residual heat removal system 50 added in this embodiment is as follows.

The driven residual heat removal system 50 is configured to remove residual heat generated from the core even after the core is stopped in the case of a coolant loss accident.

When an accident occurs, the water supply valve 2 installed in the water supply pipe 1 is closed, and the steam discharge valve 5 installed in the steam discharge pipe 4 is closed. In the event of an accident, a circulation valve 57 installed in the lower circulation pipe 55 is opened.

In case of low and high pressure of the reactor, the high pressure safety injection heat exchanger 60 takes the heat of the reactor coolant flowing along the pressure balance pipe 42 by the circulation of the cooling water provided from the passive residual heat removal heat exchanger 52, and thereby cools the reactor coolant. Can be cooled.

Cooling water passing through the high pressure safety injection heat exchanger (60) flows along the upper circulation pipe (56) and the upper connection pipe (53) and is cooled by the heat exchanger (52) for removing residual residual heat, and then the lower connection pipe (54) and Flow along the lower circulation pipe 55 is circulated to the high pressure safety injection heat exchanger (60).

The passive residual heat removal heat exchanger (52) is cooled by the coolant contained in the coolant storage unit (51), and is connected to the high pressure safety injection heat exchanger (60) through the upper circulation pipe (56) and the lower circulation pipe (55). The cooling water circulated can be cooled.

Since the other components are the same as or similar to the above-described embodiment of FIG. 1, redundant descriptions will be omitted.

In the present invention, the coolant storage unit 51, the passive residual heat removal heat exchanger 52, and the high-pressure safety injection heat exchanger 60 may be selectively applied to the reactor having the pre-injection device 100 of the present invention. have.

In the above-described first and second embodiments, a separate reactor is described, but the coolant storage unit 51, the passive residual heat removal heat exchanger 52, and the high-pressure safety injection heat exchanger 60, etc., are connected to the separate reactor or the integrated reactor. May be applied.

1: water supply line 2: water supply valve
3: water supply system 4: steam discharge pipe
5: steam release valve 6: turbine system
10 reactor vessel 11: reactor core
20: steam generator 21: heat exchanger tube
22: high temperature tube 23: reactor coolant pump
24: low temperature pipe 30: pressurizer
31: jungle pipe 100, 200: safety injection device
40: safety injection tank 41: safety injection piping
42: pressure balance piping 43: check valve
44: pressure balance valve 50: passive residual heat removal system
51: cooling water storage unit 52: heat exchanger for removing passive residual heat
53: upper connection pipe 54: lower connection pipe
55: lower circulation pipe 56: upper circulation pipe
57: circulation valve 58: check valve
60: high pressure safety injection heat exchanger
61: first heat exchanger tube 62: second heat exchanger tube

Claims (14)

A reactor vessel in which a reactor coolant is accommodated;
A steam generator disposed outside the reactor vessel and generating steam using heat generated from the reactor coolant;
A high temperature tube connected to one side of the reactor vessel and the steam generator, and supplying the reactor coolant from the reactor vessel to the steam generator;
A pressurizer connected to the high temperature pipe through a jungle pipe and configured to adjust a pressure of the reactor coolant;
A low temperature tube connected to the other side of the steam generator and the reactor vessel and recovering the reactor coolant exchanged from the steam generator to the reactor vessel; And
And a safety injection device for injecting reactor coolant into the reactor vessel when the pressure inside the reactor vessel falls below a predetermined pressure.
The safety injection device,
A safety injection tank accommodating the reactor coolant therein and disposed higher in the upward direction than the reactor vessel;
One side is connected in communication with the lower portion of the safety injection tank, the other side is connected in communication with the interior of the reactor vessel, safety injection for injecting the reactor coolant contained in the interior of the safety injection tank in the reactor vessel in the event of an accident pipe;
One side is connected in communication with the upper portion of the reactor vessel, the other side is a pressure balance pipe connected in communication with the upper portion of the safety injection tank; And
And a passive residual heat removal system for removing residual heat of the core when the core installed in the reactor vessel is stopped.
The driven residual heat removal system,
A coolant storage unit disposed outside the reactor vessel;
Passive residual heat condensed in the steam generator which is accommodated in the cooling water inside the cooling water storage unit, is disposed outside the reactor vessel and generates steam using heat generated from the reactor coolant contained in the reactor vessel. Removal heat exchanger; And
And a high pressure safety injection heat exchanger provided in the pressure balance pipe to heat-exchange the condensate water provided from the passive residual heat removal heat exchanger and the reactor coolant discharged from the reactor vessel. The method of claim 1,
A check valve installed in the safety injection pipe; And
Further comprising a pressure balance valve installed in the pressure balance pipe,
The pressure balancing pipe is a reactor, characterized in that the selectively opening and closing according to the operation of the pressure balancing valve. The method of claim 2,
Non-condensable gas is filled in the upper space of the safety injection tank, the reactor characterized in that to pressurize the reactor coolant contained in the safety injection tank. The method of claim 3,
And the pressure balance valve is opened when the internal pressure of the reactor vessel is higher than the pressure of the non-condensable gas and closed when the pressure is lower than the pressure of the non-condensable gas. delete The method of claim 1,
The high pressure safety injection heat exchanger is a reactor characterized in that the water-cooled heat exchanger cooled by the cooling water. The method of claim 6,
The high pressure safety injection heat exchanger is a reactor characterized in that the heat exchanger of one of the fin and tube type, plate type and printed plate type heat exchanger. delete delete delete The method of claim 1,
The passive residual heat removal system
One side is connected to the steam discharge pipe for discharging the steam from the steam generator, the other side is connected to the heat exchanger for the passive residual heat removal, the upper connection pipe for supplying the steam to the heat exchanger for the residual residual heat removal; And
One side is connected to the heat exchanger for removing the residual heat of the driven, the other side is connected to the water supply pipe for supplying the cooling water to the steam generator, characterized in that it comprises a lower connection pipe for recovering the condensate heat exchanged in the steam generator to the steam generator Reactor. The method of claim 11,
The driven residual heat removal system,
One side is connected to the high pressure safety injection heat exchanger, the other side is connected to the upper connection pipe, the upper circulation pipe for circulating the steam of the cooling water passing through the high pressure safety injection heat exchanger to the passive residual heat removal heat exchanger; And
One side is connected to the lower connection pipe, the other side is connected to the high pressure safety injection heat exchanger, characterized in that it comprises a lower circulation pipe for supplying the condensed water passed through the passive residual heat removal heat exchanger to the high pressure safety injection heat exchanger Reactor. The method of claim 12,
The driven residual heat removal system,
A check valve installed in the upper circulation pipe to prevent backflow of the cooling water vapor; And
And a circulation valve installed in the lower circulation pipe so as to be openable and closed, and selectively circulating the condensed water to one of the high pressure safety injection heat exchanger and the steam generator. The method of claim 1,
The high pressure safety injection heat exchanger,
A first heat exchange tube connected to the pressure balance pipe and through which the reactor coolant flows; And
And a second heat exchanger tube connected to the driven residual heat removing heat exchanger and flowing condensed water condensed in the driven residual heat removing heat exchanger.

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